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Ch 10'4: Even and Odd Functions

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Title: Ch 10'4: Even and Odd Functions


1
Ch 10.4 Even and Odd Functions
  • Before looking at further examples of Fourier
    series it is useful to distinguish two classes of
    functions for which the Euler-Fourier formulas
    for the coefficients can be simplified.
  • The two classes are even and odd functions, which
    are characterized geometrically by the property
    of symmetry with respect to the y-axis and the
    origin, respectively.

2
Definition of Even and Odd Functions
  • Analytically, f is an even function if its domain
    contains the point x whenever it contains x, and
    if f (-x) f (x) for each x in the domain of f.
    See figure (a) below.
  • The function f is an odd function if its domain
    contains the point x whenever it contains x, and
    if f (-x) - f (x) for each x in the domain of
    f. See figure (b) below.
  • Note that f (0) 0 for an odd function.
  • Examples of even functions
  • are 1, x2, cos x, x.
  • Examples of odd functions
  • are x, x3, sin x.

3
Arithmetic Properties
  • The following arithmetic properties hold
  • The sum (difference) of two even functions is
    even.
  • The product (quotient) of two even functions is
    even.
  • The sum (difference) of two odd functions is odd.
  • The product (quotient) of two odd functions is
    even.
  • The product (quotient) of an odd and an even
    function is odd.
  • These properties can be verified directly from
    the definitions, see text for details.

4
Integral Properties
  • If f is an even function, then
  • If f is an odd function, then
  • These properties can be verified directly from
    the definitions, see text for details.

5
Cosine Series
  • Suppose that f and f ' are piecewise continuous
    on -L, L) and that f is an even periodic
    function with period 2L.
  • Then f(x) cos(n? x/L) is even and f(x) sin(n?
    x/L) is odd. Thus
  • It follows that the Fourier series of f is
  • Thus the Fourier series of an even function
    consists only of the cosine terms (and constant
    term), and is called a Fourier cosine series.

6
Sine Series
  • Suppose that f and f ' are piecewise continuous
    on -L, L) and that f is an odd periodic function
    with period 2L.
  • Then f(x) cos(n? x/L) is odd and f(x) sin(n? x/L)
    is even. Thus
  • It follows that the Fourier series of f is
  • Thus the Fourier series of an odd function
    consists only of the sine terms, and is called a
    Fourier sine series.

7
Example 1 Sawtooth Wave (1 of 3)
  • Consider the function below.
  • This function represents a sawtooth wave, and is
    periodic with period T 2L. See graph of f
    below.
  • Find the Fourier series representation for this
    function.

8
Example 1 Coefficients (2 of 3)
  • Since f is an odd periodic function with period
    2L, we have
  • It follows that the Fourier series of f is

9
Example 1 Graph of Partial Sum (3 of 3)
  • The graphs of the partial sum s9(x) and f are
    given below.
  • Observe that f is discontinuous at x ?(2n 1)L,
    and at these points the series converges to the
    average of the left and right limits (as given by
    Theorem 10.3.1), which is zero.
  • The Gibbs phenomenon again occurs near the
    discontinuities.

10
Even Extensions
  • It is often useful to expand in a Fourier series
    of period 2L a function f originally defined only
    on 0, L, as follows.
  • Define a function g of period 2L so that
  • The function g is the even periodic extension of
    f. Its Fourier series, which is a cosine series,
    represents f on 0, L.
  • For example, the even periodic extension of f (x)
    x on 0, 2 is the triangular wave g(x) given
    below.

11
Odd Extensions
  • As before, let f be a function defined only on
    (0, L).
  • Define a function h of period 2L so that
  • The function h is the odd periodic extension of
    f. Its Fourier series, which is a sine series,
    represents f on (0, L).
  • For example, the odd periodic extension of f (x)
    x on 0, L) is the sawtooth wave h(x) given
    below.

12
General Extensions
  • As before, let f be a function defined only on
    0, L.
  • Define a function k of period 2L so that
  • where m(x) is a function defined in any way
    consistent with Theorem 10.3.1. For example, we
    may define m(x) 0.
  • The Fourier series for k involves both sine and
    cosine terms, and represents f on 0, L,
    regardless of how m(x) is defined.
  • Thus there are infinitely many such series, all
    of which converge to f on 0, L.

13
Example 2
  • Consider the function below.
  • As indicated previously, we can represent f
    either by a cosine series or a sine series on 0,
    2. Here, L 2.
  • The cosine series for f converges to the even
    periodic extension of f of period 4, and this
    graph is given below left.
  • The sine series for f converges to the odd
    periodic extension of f of period 4, and this
    graph is given below right.
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